Abstract

Autism Spectrum Disorder (ASD) is a developmental disorder characterized by inappropriate responses to social and sensory stimulation, restricted communication, and stereotyped behavior. Heterozygous mutations in the gene Pten (phosphatase and tensin homolog on chromosome 10) have been identified in 5 to 17% of patients presenting with autism and macrocephaly. Further, experimental deletion of Pten in the mouse brain also causes macrocephaly and deficits in social behavior, suggesting a causative role for Pten dysfunction in the development of ASD. At the cellular level, Pten knockdown results in aberrant growth and increased excitatory synaptic function. Thus, study of Pten fits perfectly with our long-term goal of understanding how synaptic connectivity and activity contribute to complicated cognitive and emotional functions. Our central hypothesis is that Pten dysfunction in autism patients results in aberrant excitation of susceptible neural circuits. Guided by this hypothesis, the specific aims of this proposal will strengthen our understanding of the molecular and neurophysiological basis of ASD. Manipulation of Pten in vivo presents a unique opportunity to examine the neurophysiological basis of autism in a model organism.
Our first aim will test the hypothesis that Pten knockdown results in hyperexcitability of a defined circuit. The symptoms of autism are often most severe during development, and decrease in severity during adolescence and adulthood. Identification of endogenous mechanisms by which the adult brain becomes more resistant to genetic insults causing autism could lead to new treatments.
Our second aim will test the hypothesis that developing neurons are intrinsically more sensitive to the effects of Pten knockdown. A key gap in our understanding of how Pten contributes to autism exists because we have not examined whether Pten point mutations are equivalent to knockdown. Examining point mutations found in patients will serve as a starting point to identify intra- and intermolecular interactions of Pten relevant to the autism phenotype. For the third aim, we will test the hypothesis that point mutations identified in patients will reslt in cellular phenotypes relevant to the autism model. This proposal will use the innovative approaches of viral-based knockdown and molecular substitution in vivo, coupled with detailed morphological and electrophysiological analyses. The broad goal of this research is to define the molecular and physiological basis of how Pten dysfunction contributes to some forms of autism.

Public Health Relevance

This research proposal is relevant to public health because it addresses issues related to the molecular pathophysiology of autism spectrum disorder. Thus it is directly relevant to the part of NIH's mission outlined in PA-10-158 - Research on Autism and Autism Spectrum Disorders.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Mental Health (NIMH)
Type
Research Project (R01)
Project #
5R01MH097949-02
Application #
8509791
Study Section
Developmental Brain Disorders Study Section (DBD)
Program Officer
Panchision, David M
Project Start
2012-07-15
Project End
2017-06-30
Budget Start
2013-07-01
Budget End
2014-06-30
Support Year
2
Fiscal Year
2013
Total Cost
$375,706
Indirect Cost
$135,706

  Institution

Name
Dartmouth College
Department
Physiology
Type
Schools of Medicine
DUNS #
041027822
City
Hanover
State
NH
Country
United States
Zip Code
03755

  Publications

Rahme, Gilbert J; Luikart, Bryan W; Cheng, Chao et al. (2018) A recombinant lentiviral PDGF-driven mouse model of proneural glioblastoma. Neuro Oncol 20:332-342
Fricano-Kugler, Catherine J; Getz, Stephanie A; Williams, Michael R et al. (2018) Nuclear Excluded Autism-Associated Phosphatase and Tensin Homolog Mutations Dysregulate Neuronal Growth. Biol Psychiatry 84:265-277
Galinato, M H; Lockner, J W; Fannon-Pavlich, M J et al. (2018) A synthetic small-molecule Isoxazole-9 protects against methamphetamine relapse. Mol Psychiatry 23:629-638
Luikart, Bryan W (2017) Can fearlessness come in a tiny package? Elife 6:
Howe 6th, James R; Li, Emily S; Streeter, Sarah E et al. (2017) MiR-338-3p regulates neuronal maturation and suppresses glioblastoma proliferation. PLoS One 12:e0177661
Fricano-Kugler, Catherine J; Williams, Michael R; Salinaro, Julia R et al. (2016) Designing, Packaging, and Delivery of High Titer CRISPR Retro and Lentiviruses via Stereotaxic Injection. J Vis Exp :
Smith, Kyle S; Bucci, David J; Luikart, Bryan W et al. (2016) DREADDS: Use and application in behavioral neuroscience. Behav Neurosci 130:137-55
Williams, Michael R; Fricano-Kugler, Catherine J; Getz, Stephanie A et al. (2016) A Retroviral CRISPR-Cas9 System for Cellular Autism-Associated Phenotype Discovery in Developing Neurons. Sci Rep 6:25611
Moen, Erika L; Fricano-Kugler, Catherine J; Luikart, Bryan W et al. (2016) Analyzing Clustered Data: Why and How to Account for Multiple Observations Nested within a Study Participant? PLoS One 11:e0146721
Getz, Stephanie A; DeSpenza Jr, Tyrone; Li, Meijie et al. (2016) Rapamycin prevents, but does not reverse, aberrant migration in Pten knockout neurons. Neurobiol Dis 93:12-20

Showing the most recent 10 out of 14 publications